Effects of glucose on the uptake and metabolism of glycine in pakchoi (Brassica chinensis L.) exposed to various nitrogen sources
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Plants can absorb amino acids as a nitrogen (N) source, and glucose is an important part of root rhizodeposition and the soil sugar pool, which participates in the regulation of plant growth and uptake. In pakchoi, the effect of glucose concentration on the glycine N uptake from a nutrient mixture composed of glycine, ammonium, and nitrate, or from a single N solution of glycine alone was studied using specific substrate 15N-labeling and 15N-gas chromatography mass spectrometry.
The optimal glucose concentration for plant growth was 4.5 μM or 25 μM when supplied with glycine alone or the N mixture, respectively, and resulted in a >25% increase in seedling biomass. The addition of glucose affected the relative contribution from organic or inorganic sources to overall N uptake. When glucose was added at optimal concentrations, glycine was preferentially used as an N source, while the relative contribution from nitrate was reduced. The limiting step for glycine N contribution was active uptake in the roots in high glucose and single-N-source conditions; however, root metabolism of glycine to serine was limiting in high-glucose and mixed-N-source conditions.
The addition of low concentrations of glucose increased the relative uptake of organic nitrogen and reduced the uptake of nitrate, suggesting a feasible way to decrease nitrate content and increase the edible quality of vegetables.
KeywordsBrassica chinensis Glucose Glycine Nitrogen uptake Rhizodeposition Soil nutrients
Protonophore carbonyl cyanide M-chlorophenylhydrazone
Gas chromatography–mass spectrometry
Glutamine oxoglutarate aminotransferase
Glutamic oxaloacetic transaminase
Serine glyoxalate aminotransferase
Nitrogen (N) is a major component of proteins and is important for plant growth. To date, most studies of N uptake focus on inorganic N sources such as ammonium and nitrate and have shown that the addition of excess inorganic N has significant negative effects on both soil and environmental health . In contrast to inorganic N, organic N sources from amino acids, nucleic acids, quaternary ammonium compounds, and proteins can be directly acquired and metabolised by plants [2, 3, 4, 5], bypassing the need for decomposition by microorganisms. Amino acids account for more than 50% of the total N uptake in low-temperature ecosystems including the arctic, alpine tundras, boreal forests, and heathlands [6, 7, 8, 9]. Although the actual contribution of amino acids to overall N uptake in natural environments has not been determined due to the lack of an accurate assessment method, organic N, especially amino acids, may be an unrecognised resource for plant N nutrition.
The uptake and metabolism of organic N is affected by several abiotic and biotic factors that include light intensity, pH, soil moisture and texture, and CO2 level [10, 11, 12, 13, 14]. For example, at 11 °C glycine uptake is limited, while at 21 °C the metabolic conversion of glycine to serine is the limiting step in its N contribution . In a previous study, we showed that higher light intensities increased the uptake of glycine and nitrate, and lower light intensities increased the percentage of ammonium uptake; moreover, we found that the metabolism of ammonium produced by glycine might limit the relative contribution from glycine to the overall N uptake under high light conditions . An in-depth understanding of how environmental factors affect N uptake and metabolism could aid in regulating plant nutrition and the data could be used to predict the future performance of plants in response to global climate change.
Nitrogen uptake and metabolism are closely linked to carbon (C) content, as the carbon skeleton is essential for the assimilation of inorganic N into amino acids, nucleic acids, and proteins . Enhanced supplies of C increase the uptake and metabolism of N [18, 19] because the process of N metabolism requires energy and C skeleton consumption . Multiple studies have shown that N-responsive genes are closely related to C signalling pathways [21, 22], but the mechanisms associated with crosstalk between C and N remain obscure . Therefore, an in-depth knowledge of these interconnections could aid in understanding the regulation of plant nutrition especially N uptake and ultimately apply to crop quality improvement.
The effect of sugars on nitrate uptake is well studied, but no studies have examined the effect of sugars on amino acid uptake and metabolism. Sugars enhance nitrate reductase activity and decrease its degradation . Therefore, changes in the sugar supply can lead to alterations in the expression of numerous genes involved in ammonium metabolism, nitrate uptake, reduction, amino acid synthesis, and protein synthesis . De et al. (2014) suggested that sucrose in roots affects both NO3 − transporters and assimilatory genes, and showed that glucose stimulates the expression level of the high-affinity transporter NRT2.1 protein and nitrate transport activity independent of the stimulation of protein expression. It has also been demonstrated that post-transcriptional mechanisms influence NO3 − uptake in response to sucrose . Remarkably, most experiments have been conducted with nitrate only, and information on the effects sugar has on the relative uptake of different sources of N is limited. It is interesting that amino acids can be taken up by plants directly and that partial replacement of nitrate by amino acids could improve vegetable quality; however, they also reduce biomass compared to nitrate supplementation . The absorption of amino acids by plant roots is associated with two benefits: 1) amino acids are already in the required reduction state for N uptake, which saves the energy required for inorganic N metabolism; and 2) the assimilation of pre-formed carbon skeletons from organic nitrogen sources reduces the biosynthetic costs of plant growth . Consequently, the effects of externally supplied C on amino acid uptake and metabolism may differ with the source of inorganic N and may alter the relative uptake of inorganic and organic forms of N.
Pakchoi (Brassica chinensis L.) is cultivated over a large northern to southern range in China. Most soil solutions contain high glycine content , and therefore, we selected it as a representative amino acid for testing how glucose affects N uptake in pakchoi. To avoid the decomposition of amino acids by microorganisms, pakchoi seedlings were hydroponically cultivated in a sterilised environment and 15N labelling was used to test the following: (1) how glucose affects pakchoi growth and the relative uptake of different N forms; (2) how different glucose concentrations affect the uptake and metabolism of glycine; and (3) whether the effect of glucose on glycine uptake and metabolism was influenced by the N supply.
Seedling culture conditions
Pakchoi plants were cultured in a sterile environment as described . Briefly, pakchoi seeds (provided by Zhejiang Academy of Agricultural Sciences) were soaked in purified water overnight and then sterilised using the method previously described . The seeds were placed into sterilised culture dishes for 3 d with day/night temperatures of 25/20 °C, humidity of 60%/40%, and a 12 h light cycle (360 μmol⋅m−2⋅s−1). Seedlings were transferred to a 50-mL centrifuge tube containing 0.3% cooled agar dissolved in water and placed in a sterilised culture room under the aforementioned conditions. After 1 day of growth, the seedlings began to grow out of the holes in the tube caps and the holes were then sealed with silicone rubber (Nanda 704, China). The seedling and the tube cap were transferred to a new centrifuge tube that was filled with a nutrient solution. The nutrient solution contained 2 mM K2SO4, 4 mM CaCl2, 1.4 mM MgSO4 · 7H2O, 2 mM KH2PO4, 0.1 μM NaMoO4 · 2H20, 1 μM ZnSO4 · 7H2O, 0.4 μM CuSO4 · 5H2O, 8 μM H3BO3, 5 μM Na2EDTA, 18.3 μM FeSO4 · 7H2O, and 10 μM MnCl2. The pH of the solution was adjusted to 6.2, and the composition of solution were the same in each experiment (except N). The N mixtures used in the different experiments were filter-sterilised through a 0.22-μm membrane filter (Millipore, PES Membrane, Ireland) and added to the nutrient solution before use. The materials and nutrient solution without N were autoclaved at 121 °C for 30 min. The nutrient solutions were changed every 3 d at a clean bench in the sterilised culture room.
Experiment 1: Effect of glucose concentration on the growth and N uptake in pakchoi
Pakchoi seedlings were pre-cultured as described in 3 mM mixed N (1 mM glycine + 1 mM nitrate + 1 mM ammonium) for 6 d before 48 similarly sized seedlings were selected for experimentation to compensate for the natural growth difference in plant populations. Glucose was then added at concentrations of 0, 1.5, 4.5, 10, 25, 50, 500, and 5,000 μM to the nitrogen-containing nutrient solutions and the mixtures were filter-sterilised. The seedlings were cultured as described for 15 d with sufficient nutrient supply, after which shoots and roots were harvested separately. The roots were washed in 50 mM CaCl2 in an ultrasonic bath for 1 min and then washed three more times in purified water. The shoots and roots were freeze-dried (Labconco Freeze System, USA) and ground into a fine powder using a ball mill (Retsch MM301, Germany). The N content was determined in six replicates from each treatment using the Micro-Kjeldahl method.
Seventy-two similar seedlings were pre-cultivated for 15 d, after which the roots and centrifuge tubes were washed with sterilised purified water. The seedlings were cultivated in 1 mM 10.0% 15N-glycine with glucose concentrations of 0, 0.5, 1.5, 4.5, 10, 25, 50, and 500 μM for 15 d before the shoots and roots were harvested separately. The highest glucose level (5,000 μM) was not used because it killed the pakchoi seedlings. Three seedlings were pooled to account for variation between plants in each treatment, and each treatment was replicated three times. The roots were washed and the shoots and roots were freeze-dried separately and ground into a powder as described above. The N content and 15N incorporation into the samples were determined using an Elemental Analysis-Stable Isotope Mass Spectrometer (IsoPrime100, UK). In addition, three “blank” seedlings were reserved for each treatment by providing unlabelled N at the same composition as the treated plants. This control design was the same in Experiments 2 and 3 as well. The variation in the growth between the different treatments can affect the natural 15N abundance in tissues; therefore, we detected N content for each treatment, and three seedlings were pooled and treated as one replicate.
Experiment 2: Effect of glucose on the N contribution from ammonium, nitrate, and glycine using mixed sources of N
Pakchoi was pre-cultivated as described in Experiment 1 for 6 d, and 81 similar seedlings were selected. The glucose concentrations used were 0, 25 (the optimal concentration for pakchoi growth as shown in Experiment 1), and 500 μM (an excessive concentration for pakchoi growth); and three N mixtures of the same concentration were prepared for each glucose condition (1 mM NO3 −, NH4 +, and glycine) where only one N source was labelled by 15N (5.0% 15NO3 −, 5.0% 15NH4 +, or 5.0% 15N-glycine). For example, under 500 μM glucose, the N mixtures were composed of NO3 −:NH4 +:15N-glycine, NO3 −:15NH4 +:glycine, or 15NO3 −:NH4 +:glycine, and the N uptake and contribution from the different N sources could be separated based on this labelling scheme. The nine treatments (3 N sources × 3 glucose concentrations) were replicated three times, the cultivation solution was changed every 3 d, and the plants were harvested at 21 d. The shoots and roots were harvested separately and three seedlings were pooled into a single sample. The samples were washed, dried, ground, and the 15N content was detected as described in Experiment 1.
Experiment 3: Effect of glucose on the short-term uptake of glycine
Pakchoi seedlings were pre-cultivated for 25 d and 180 similar seedlings were selected. Seedlings were “starved” overnight in an N-free nutrient solution before beginning the short-term (4 h) glycine uptake tests. The glucose concentration in this experiment was determined based on the N source. The optimal glucose concentration for pakchoi growth was 4.5 μM when a single N source was used and 25 μM under the mixed nitrogen conditions (Experiment 1). Therefore, 45 seedlings were cultivated in 1 mM 98.10% 15N-glycine for 4 h at glucose concentrations of 0, 4.5, and 500 μM; and an additional 45 seedlings were cultivated for 4 h with 1 mM NO3 − + 1 mM NH4 + + 1 mM 98.10−15N-glycine at glucose concentrations of 0, 25, and 500 μM.
Simultaneously, the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP) , that inhibits the active uptake of glycine was used to examine the effect of glucose on the active and passive uptake of glycine. Ninety seedlings were starved overnight in an N-free nutrient solution and pre-treated with 50 μM CCCP for 1 h, after which 45 seedlings were cultivated for 4 h with either 1 mM 98.10%-15N-labelled glycine in glucose concentrations of 0, 4.5, and 500 μM, or 1 mM NO3 − + 1 mM NH4 + + 1 mM 98.10 15N-glycine in 0, 25, and 500 μM glucose. The uptake tests for CCCP-treated and untreated specimens were conducted simultaneously with three replicates per treatment. The roots and shoots were harvested separately and five seedlings were pooled as one sample for each experimental replicate. The roots were washed, dried, and analysed as described in Experiment 1. The 15N values obtained from CCCP-treated samples represented the passive uptake of glycine in pakchoi.
Experiment 4: Effect of Glucose on N metabolic enzyme activity
After root N uptake, several enzymes metabolise glycine; is the metabolism of glycine changed by the uptake of glycine? Ninety-six seedlings were pre-cultured for 22 d and then starved overnight as previously described in Experiment 3. Forty-eight seedlings were cultivated for 4 d in 1 mM glycine in glucose concentrations of 0, 4.5, and 500 μM. The remaining 48 seedlings were cultivated in glucose concentrations of 0, 25, and 500 μM added to a mixed N source solution of 1 mM NO3 − + 1 mM NH4 + + 1 mM glycine. The nutrient solution was changed every 2 d. The seedlings were harvested and six seedlings were pooled to represent one sample in each of the four experimental replicates. The activities of glutamine synthetase (GS) , glutamic-pyruvic transaminase (GPT), and glutamic oxaloacetic transaminase (GOT)  were measured in roots and shoots.
Experiment 5: Effect of glucose on amino acid content of pakchoi
Pakchoi seedlings were pre-cultured for 25 d and the 72 uniform seedlings were washed and N-starved overnight. They were then cultivated in 1 mM NO3 − + 1 mM NH4 + + 1 mM glycine with 0, 25, and 500 μM glucose for 12 h (25 °C, 60% humidity, 360 μmol⋅m−2⋅s−1 light). The shoots and roots were harvested separately and the roots were washed as described in Experiment 1. The experiment included six replicates with four seedlings in each replicate to reduce individual plant variation. Aliquots of 1 g fresh shoots and roots were ground in 4 ml of 5% sulfosalicylic acid and incubated for 1 h. The extracts were centrifuged at 14 000 × g for 10 min and the supernatant was passed through a 0.22-μm membrane filter (Millipore, PES Membrane, Ireland). Amino acid content was measured with an automatic amino-acid analyzer (L-8900, Hitachi, Japan).
Experiment 6: Effect of glucose on the metabolism of glycine
Pakchoi seedlings were pre-cultured for 25 d and 96 similar seedlings were selected for further cultivation. The roots were washed several times with purified water and the seedlings were N-starved for 12 h. Then, the seedlings were cultivated in 1 mM NO3 − + 1 mM NH4 + + 1 mM 98.1% 15N-glycine with 25 μM and 500 μM glucose for 12 h (25 °C, 60% humidity, 360 μmol⋅m−2⋅s−1 light). The pakchoi roots and shoots were harvested separately; eight seedlings per treatment were pooled and each treatment had 6 replicates. The roots were washed, dried, and ball milled as previously described. The 15N-labelled amino acids were detected by gas chromatography–mass spectrometry (GC-MS) as previously described  with minor modifications. Briefly, 20 mg aliquots of ball milled root and shoot samples were extracted in 3 ml 80% ethanol for 1 h with gentle shaking every 10 min. The extracted solutions were centrifuged at 3,500 × g for 15 min and the supernatant was collected. The extraction and centrifugation of these samples was repeated once more. Each supernatant from the two extractions were combined and dried in a rotary evaporator (EYELA, SB-1100) at 25 °C and resuspended in 1 ml of 0.1 M hydrochloric acid. This solution was centrifuged at 12,000 × g for 15 min and the supernatant was added to the Dowex 50WX8-200 cation exchange columns (Sigma-Aldrich, St Louis, MO, USA) (2 ml bed volume, H+ form). The cation exchange columns were washed with 20 ml ultrapure water, and 20 ml of 4 M ammonia solution was used to wash out the amino acids. The eluate was blown for 8 h with N2 to remove the NH3, and then freeze-dried (Labconco Freezen System, U.S.A.). Amino acids in the resultant extracts were derivatised to t-butyldimethylsilyl in 10 μL N-methyl-N-tert-butyldimethylsilyl-trifluoroacetamide. Finally, the 15N-labelled amino acids in the roots and shoots were detected by GC-MS.
Data are presented as the mean ± standard error (SE). We applied one-way analysis of variance (ANOVA) followed by Duncan’s multiple range method (p < 0.05) to assess differences between treatments. All statistical analyses were performed using SAS 8.2 (SAS Institute Inc., Cary, NC). Figures were created using Origin 8.1 (OriginLab, Northampton, MA).
Low concentrations of glucose preferentially increase long-term N uptake and pakchoi biomass
Glucose preferentially enhances glycine-derived N uptake from mixed N sources
Glucose concentrations affect the active short-term uptake and transport of glycine
Glucose concentration can alter the activity of glycine metabolic enzymes in mixed-N conditions
Effects of glucose on the activity of N metabolic enzymes in pakchoi
Glucose concentration (μM)
GPT (μmol · g-1 · 30 min)
GOT (μmol · g-1 · 30 min)
GS (A · mg-1 protein · h-1)
3.8 ± 0.4a
7.8 ± 1.5a
9.8 ± 0.2ab
12.5 ± 0.2a
19.1 ± 0.7a
23.5 ± 0.6a
5.7 ± 1.3a
5.7 ± 0.8ab
10.3 ± 0.1a
11.9 ± 0.5a
19.9 ± 0.2a
24.5 ± 2.9a
5.9 ± 0.6a
3.9 ± 0.5b
9.6 ± 0.2b
11.2 ± 0.3a
21.3 ± 1.8a
23.4 ± 0.9a
4.5 ± 0.9a
5.2 ± 2.7a
12.1 ± 0.2a
13.8 ± 0.4a
19.2 ± 0.4b
24.7 ± 1.0a
5.1 ± 0.5a
6.3 ± 1.8a
10.5 ± 0.2b
13.2 ± 0.3a
23.0 ± 0.8a
24.0 ± 0.9a
5.9 ± 1.2a
7.2 ± 0.8a
10.2 ± 0.1b
13.1 ± 0.1a
20.7 ± 0.5b
20.5 ± 0.5b
Amino acid content in pakchoi is altered by external glucose concentrations
15N-labelled amino acid levels in shoots and roots are affected by glucose supplementation
Effects of glucose on pakchoi growth and N uptake depend on the N conditions
The results of this study indicate that relatively low concentrations of glucose accelerated pakchoi growth, while excessive glucose levels retarded both growth and N accumulation (Fig. 1). A previous study showed that high glucose in plants reduced the rates of photosynthesis and sugar transport, and low glucose in plants led to increased sugar transport activities . In our study, we found that glucose levels alter N uptake, indicating that its regulation is another example of how glucose affects pakchoi growth. The optimal glucose concentration for pakchoi grown in a mixed N source conditions was 25 μM, which is more than five times higher than that observed in single N conditions. This result indicates that the effect of glucose on pakchoi growth is related to the N supply. Similarly, nitrate levels affected the glucose sensitivity of wild-type Arabidopsis during germination . There is a growth inhibition effect at 3% (166 mM) glucose with only 0.1 mM nitrate, but this inhibitory effect was not observed at 5% (275 mM) glucose with either 1 or 5 mM nitrate. In addition, optimal glucose concentrations were found to be 1–3% (55–166 mM) in Arabidopsis thaliana seedlings cultivated on agar media , which is hundreds of times higher than the optimal concentrations (4.5 or 25 μM) we detected in pakchoi. This large discrepancy may be caused by differences between the plant species and the glucose availability dissolved in water versus that in agar.
Plants possess the ability to take up sugars, which can regulate plant growth and N uptake. Massive amounts of sugar were detected in the xylem sap, which indicated that the glucose in roots might be acropetally transported to the shoots and leaves [37, 38]. Glucose is not only regarded as an energy and carbon resource for biomass production, but it also acts as a rapid molecular signal to coordinate root and shoot development . We show that the optimal concentrations of glucose (4.5 or 25 μM) for pakchoi growth were very low and therefore, might play little role in providing energy and C skeletons for biosynthesis, which suggests that the positive effect of lower glucose concentrations on pakchoi growth results from its role as a signal molecule.
Effects of glucose on the relative uptake of glycine, nitrate, and ammonium
Several studies have shown that biotic and abiotic factors affect the uptake and metabolism of organic and inorganic N. The optimal glucose concentration increased the relative N contribution from glycine; however, it decreased the N contribution from nitrate and both the optimal and high glucose concentrations decreased the N contribution from ammonium (Fig. 2). Nitrate taken up by roots is transferred to ammonium and assimilated into glutamine by GS, which needs C skeletons for amino acid assimilation [39, 40]. Compared to amino acids, externally supplied glucose may theoretically have a significantly positive effect on the uptake of inorganic N due to the high C demand of inorganic N. However, the opposite effect was observed, as the uptake and N contribution from nitrate in mixed N source conditions was lower at optimal and high glucose concentrations than in glucose-free conditions (Fig. 2b, d). These results could be explained in two ways: first, most studies were conducted under single N source conditions, which neglects to consider the effect of other N sources on the uptake of nitrate. In other words, the uptake of one form of N has an effect on the uptake of other forms [15, 41]. For example, ammonium hinders the uptake of nitrate and the addition of amino acids inhibits the uptake of both ammonium and nitrate . Therefore, the increased uptake of glycine could inhibit the uptake of ammonium and nitrate, as we observed in pakchoi. Second, the optimal glucose concentrations (4.5–25 μM) are very low compared to the concentration of sugars in the plant itself [37, 38], suggesting that sugar may be involved in nutrient signalling and regulation, rather than act as C source.
Significant differences were detected between the relative N contributions from nitrate and glycine in shoots and roots (Fig. 2b, d). Nitrate contributed 26.4–35.3% of total N in shoots, while it accounted for only 14.4–19.8% in roots. By contrast, glycine accounted for 27.6–37.5% and 35.0–44.3% in shoots and roots, respectively. The N contribution of nitrate in shoots was much higher than it in roots, while the contribution of glycine in shoots was much lower than it in roots. This difference likely resulted from variations in both N transportation and metabolism in these two tissues. Most nitrate taken up by roots is transported to and metabolized in shoots , which leads to relatively high N levels in shoots. Plants can take up amino acids at a faster rate than nitrate [15, 43, 44]; however, most amino acids are metabolized in the roots  and amino acids are allocated to shoots at a slower rate than nitrate . Overall, the differences in the metabolism of glycine and nitrate resulted in significant differences in their relative N contributions.
The objective of reducing nitrate content in vegetables is important because of its potential impact on human health. For example, 80% of human dietary intake of nitrate comes from vegetables  and the consumption of leafy vegetables can lead to excessive nitrate ingestion . Excessive amounts of ingested nitrate could be converted to nitrite, which can result in serious potential threats to human health, including the accumulation of carcinogenic nitrosamines or methemoglobinemia . The partial replacement of nitrate with amino acids can be an effective and feasible way to reduce the nitrate content in crop plants. By doing so, plant quality can be enhanced to improve the content of soluble sugar, soluble protein, and free amino acids; however, the biomass of vegetables may also be reduced under these nutrient conditions [49, 50]. In contrast, the present study demonstrates that a higher biomass can be achieved with the addition of glucose at concentrations of 25 μM when compared to the control treatment, and the uptake rates of glycine increase under these conditions, while nitrate uptake decreases. These results suggest that cultivation at the optimal glucose concentration might aid in the reduction of nitrate uptake over other organic N sources, which could ultimately improve vegetable quality. Moreover, studies have shown that most plants possess the ability to utilise amino acids as an N source, but the N contribution from glycine in the sterilised environment may have been overestimated with respect to that in the natural environment. Our results clearly show that pakchoi possesses a strong ability to absorb amino acids, and that glucose plays an important role in this N uptake. Therefore, the results of this study provide a new way to reduce the nitrate content in vegetables via the addition of amino acids in combination with small amounts of glucose to their cultivation conditions.
Effects of glucose on the uptake and metabolism of glycine
Environmental factors control plant growth by affecting the levels of nutrient uptake, metabolism, transport, storage, and reallocation . Studies of signalling pathways and bottlenecks in amino acid metabolism in plants grown in different environments could help improve the efficiency of N usage .
Externally supplied glucose enhanced glycine N contribution by increasing its active uptake and had little effect on its passive uptake. The optimal concentration of glucose increased the active uptake of glycine whether it was included in a single N solution of glycine or in an N mixture (Fig. 3b, e). Most amino acid uptake in plant roots is driven by H+-ATPases . This is consistent with our results that show glycine uptake in CCCP un-treated plants was 5.0–7.5 fold greater than that of CCCP-treated plants. Externally supplied glucose might improve active glycine uptake by providing energy or regulating the active uptake. Further research is needed to better describe how glucose is involved in glycine uptake mechanisms in plants.
The mechanism of high glucose inhibited glycine N contribution depending on the N supply. I In the single N solutions composed of glycine alone, active glycine uptake was the limiting step in high glucose concentrations (Fig. 3). Glycine uptake was much lower when glucose was supplied at 500 μM compared to the optimal 25 μM concentration during long-term N uptake tests. In the short-term N uptake tests, the active uptake of glycine was much lower in the high glucose concentration than the optimal concentration, indicating that the active N uptake limiting factor is associated with lower N contribution. Moreover, the N metabolic enzyme activities did not differ significantly between the optimal and high glucose concentrations, suggesting that active uptake is the limiting step rather than the subsequent nitrogen metabolism (Table 1).
Plants transport 20–50% of shoot-fixed C to the roots [54, 55] and some of it is released to the soil as rhizodeposits [54, 56]. Furthermore, root rhizodeposition is regulated by several innate factors and environmental factors, such as root system architecture , soil type , and nutrient availability . Glucose is one of the largest components of rhizodeposition and the soil sugar pool, which changes constantly. We have shown that small amounts of exogenous glucose can greatly change N uptake and metabolism, which may play an important role in regulating plant responses to biotic and abiotic stress. In addition, high concentrations and availability of amino acids were detected in the rhizosphere ; thus, glucose may play an important role in regulating amino acid uptake and metabolism in the soil.
When supplied with glycine alone or the N mixture, the optimal glucose concentration for plant growth was 4.5 μM or 25 μM respectively, and resulted in the significantly increase in pakchoi biomass. Glycine was preferentially used as an N source when glucose was added at optimal concentrations, while the relative contribution from nitrate was reduced. In high glucose and single-N-source conditions, the limiting step for glycine N contribution was active uptake in pakchoi roots, while root metabolism of glycine to serine was limiting in high-glucose and mixed-N-source conditions. The addition of low concentrations of glucose increased the relative uptake of glycine and reduced the uptake of nitrate, which providing a feasible way to reduce nitrate content and increase the edible quality of vegetables.
We would like to thank Editage for English language editing.
This work was supported by the National Basic Research Program of China (2015CB150502), the National Key Research and Development Program of China (2016YFD020010X), and the National Natural Science Foundation of China (31172032).
Availability of data and materials
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.
QM and LW designed the research. QM, XC, YX, HX and XT carried out the experiments. QM, XC and LW wrote the paper. HX and XT analyzed the data. All of the authors have read and approved the final manuscript, and agreed to be accountable for all aspects of the work.
The authors declare that they have no competing interests.
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This study does not contain any research requiring ethical consent or approval.
- 10.Lonhienne TGA, Trusov Y, Young A, Rentsch D, Näsholm T, Schmidt S, Paungfoo-Lonhienne C. Effects of externally supplied protein on root morphology and biomass allocation in Arabidopsis. Sci Rep-UK. 2014;4(6186):5055.Google Scholar
- 18.Pettersson R, Mcdonald AJS, Stadenberg I. Response of small birch plants (Betula pendula Roth.) to elevated CO2 and nitrogen supply. Plant Cell Environ. 2006;16: 1115–1121.Google Scholar
- 19.Kathleen W, Helge K, Twan R, Aaron F, Fernie AR, Otto M, Claus W, Emery RJN, Christine D, Felicia H. ADP-glucose pyrophosphorylase-deficient pea embryos reveal specific transcriptional and metabolic changes of carbon-nitrogen metabolism and stress responses. Plant Physiol. 2008;149(1):395–411.Google Scholar
- 24.Bläsing OE, Gibon Y, Günther M, Höhne M, Morcuende R, Osuna D, Thimm O, Usadel B, Scheible WR, Stitt M. Sugars and circadian regulation make major contributions to the global regulation of diurnal gene expression in Arabidopsis. Plant Cell. 2005;17(17):3257–81.CrossRefPubMedPubMedCentralGoogle Scholar
- 28.Cao X, Ma Q, Zhong C, Yang X, Zhu L, Zhang J, Jin Q, Wu L. Elevational Variation in Soil Amino Acid and Inorganic Nitrogen Concentrations in Taibai Mountain. China Plos One. 2016;11(6), e157979.Google Scholar
- 29.Wu LH, Mo LY, Fan ZL, Tao QN, Zhang FS. Absorption of glycine by three agricultural species under sterile sand culture conditions. Pedosphere. 2005;15(3):286–92.Google Scholar
- 32.Lianghuan W, Shihong J, Qingnan T. The application of colormetric method on the determination of transaminase activity. Chinese Journal of Soil Science. 1998;03:41–3.Google Scholar
- 37.Wang L, Ruan YL. Shoot–root carbon allocation, sugar signalling and their coupling with nitrogen uptake and assimilation. Funct Plant Biol. 2015.Google Scholar
- 49.Güneş A, İnal A, Aktaş M. Reducing nitrate content of NFT grown winter onion plants (Allium cepa L.) by partial replacement of NO3 − with amino acid in nutrient solution. Sci Hortic-Amsterdam. 1996;65(2–3):203–8.Google Scholar
- 53.Bush DR. Proton-Coupled Sugar and Amino Acid Transporters In Plants. Annu Rev Plant Biol. 2003;44(4):513–42.Google Scholar
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